Fluid turbine

Abstract

A turbine for extracting power from a flowing fluid comprises a blade for interaction with the fluid, the blade being rotatable both about a primary axis and a blade axis. The blade axis is proximate to the blade, substantially parallel to the primary axis and spaced therefrom. Rotation actuating means is provided to rotate the blade about the blade axis in dependence upon the rotation of the blade about the primary axis such that the rotation angle of the blade about the blade axis is a function of the rotation angle of the blade about the primary axis. The rotation of the blade about the blade axis is in the same direction of rotation as the blade axis about the primary axis.

Description

FIELD OF THE INVENTION[0001]This invention relates to the extraction of power from a flowing fluid by means of a bladed turbine. Such a turbine may be used to generate electrical energy from fluid flow such as river water flow, tidal water flow or from wind.BACKGROUND OF THE INVENTION[0002]Various devices used in the extraction of energy are known in the art using two basic mechanisms: these are variously denoted by; i) “drag” or “momentum transfer” or “momentum reversal” and ii) by “lift”. Known devices typically use one or other of these mechanisms. Momentum transfer systems rely on the fluid flow pushing against a vane, paddle or blade so that the vane is pushed in the same direction as the flow. A well-known example of a momentum transfer type device is the Pelton Wheel. However, during a full rotation cycle the cups produce significant drag on the return half of the cycle and therefore the efficiency is reduced. For this reason, such designs have not found favour for wind gener...

AI Technical Summary

Benefits of technology

[0024]i) the ability of a given area of cross-section to intercept the fastest stream flow where the stream velocity is not uniform. For tidal water flow for example where the flow velocity varies with depth above the bed this may be achieved by arranging the axis of rotation to be horizontal and such that the larger flow rate occurs for the maximum momentum reversal blade orientation and lower flow occurs for the returning blade;ii) increasing the horizontal length of the blade in order to achieve a large area where the depth within the flow stream is small. In this case the length to diameter ratio of the blade can be large;iii) the ability to minimise the effects of vortex shedding and turbulence by the provision of plates at the ends of the blades which maintain the flow direction over the plates and additionally serve to protect any gearing mechanism designed to rotate the blades in (i) above;iv) the ability to optimise any interactive effects between blades and to aid efficiency by defining the relative dimensions and geometry of the blades as well as defining the interdependence of blade rotation and central axis rotation.v) the ability to redirect flow to and from the turbine thus increasing the effective capture area or increasing the effective flow velocity. It is well known that this may be achieved by the provision of guiding blades parallel to the turbine axis and which are placed ahead or behind the turbine to funnel flow into and out of the turbine.

Problems solved by technology

However, during a full rotation cycle the cups produce significant drag on the return half of the cycle and therefore the efficiency is reduced.

For this reason, such designs have not found favour for wind generation schemes, although their simplicity makes them ideal for use as anemometers for example where power efficiency is not an important consideration.

For a mechanism which utilises drag such as the Pelton wheel, the drag force is reversed over half the rotation and thus considerably reduces the efficiency.

However, these turbines suffer from inefficiency as the drag and lift contributions are not maximised, and cannot take into account factors such as blade interaction as discussed above.

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